Sun PCI High Speed Quad Port
Serial Interface Adapter
User’s Guide
Part No. 819-1207-11
May 2010, Revision A
Regulatory Compliance Statements xi
Declaration of Conformity xv
Preface xvii
1. Product Overview
1
3
2. SunHSI/U Adapter Installation
Installation Process
5
5
▼
3. SunHSI PCI Software Installation
Installation Overview
Before Installing the Software 11
Verifying the Software and Hardware Requirements 11
To Remove Older Versions of the Software 11
9
9
▼
iii
▼
▼
To Install the SunHSI Software 12
▼
4. SunHSI Utilities 17
hsip_initUtility 17
HDLC Mode 19
B. Null Modem Cable Requirements 29
Configuring Internal or External Clocking 30
C. T1 Inverted Data and Clock Signals 35
Data Signal Inversion 35
Bipolar with 8-Zero Substitution 36
HDLC Zero Insertion Algorithm 36
Clock Signal Inversion 37
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
E. Viewing the Man Pages 41
▼
▼
To View Man Pages in the C Shell Environment 41
To View Man Pages in Bourne or Korn Shell Environments 42
Glossary 43
Contents
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
viii
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
Regulatory Compliance Statements
Your Sun product is marked to indicate its compliance class:
•
•
•
•
•
•
Federal Communications Commission (FCC) — USA
Industry Canada Equipment Standard for Digital Equipment (ICES-003) — Canada
Voluntary Control Council for Interference (VCCI) — Japan
Bureau of Standards Metrology and Inspection (BSMI) — Taiwan
Certification and Accreditation Administration of the People’s Republic of China (CNCA) — China
Korea Communications Commission (KCC) — Korea
Please read the appropriate section that corresponds to the marking on your Sun product before attempting to install the
product.
FCC Class A Notice
This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions:
1. This device may not cause harmful interference.
2. This device must accept any interference received, including interference that may cause undesired operation.
Note: This equipment has been tested and found to comply with the limits for a Class A digital device, pursuant to Part 15 of
the FCC Rules. These limits are designed to provide reasonable protection against harmful interference when the equipment
is operated in a commercial environment. This equipment generates, uses, and can radiate radio frequency energy, and if it is
not installed and used in accordance with the instruction manual, it may cause harmful interference to radio communications.
Operation of this equipment in a residential area is likely to cause harmful interference, in which case the user will be required
to correct the interference at his own expense.
Modifications: Any modifications made to this device that are not approved by Sun Microsystems, Inc. may void the authority
granted to the user by the FCC to operate this equipment.
FCC Class B Notice
This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions:
1. This device may not cause harmful interference.
2. This device must accept any interference received, including interference that may cause undesired operation.
Note: This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of
the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential
installation. This equipment generates, uses and can radiate radio frequency energy and, if not installed and used in
accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee
that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or
television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the
interference by one or more of the following measures:
•
•
•
•
Reorient or relocate the receiving antenna.
Increase the separation between the equipment and receiver.
Connect the equipment into an outlet on a circuit different from that to which the receiver is connected.
Consult the dealer or an experienced radio/television technician for help.
Modifications: Any modifications made to this device that are not approved by Sun Microsystems, Inc. may void the authority
granted to the user by the FCC to operate this equipment.
xi
ICES-003 Class A Notice - Avis NMB-003, Classe A
This Class A digital apparatus complies with Canadian ICES-003.
Cet appareil numérique de la classe A est conforme à la norme NMB-003 du Canada.
ICES-003 Class B Notice - Avis NMB-003, Classe B
This Class B digital apparatus complies with Canadian ICES-003.
Cet appareil numérique de la classe B est conforme à la norme NMB-003 du Canada.
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
BSMI Class A Notice
The following statement is applicable to products shipped to Taiwan and marked as Class A on the product compliance
label.
CCC Class A Notice
The following statement is applicable to products shipped to China and marked with “Class A” on the product’s compliance
label.
Korean Class A Notice
The following is the Korean Class A Broadcasting and Telecommunication Products for Business Purpose Statement.
Regulatory Compliance Statements xiii
xiv Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
xvi Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
Preface
This document provides information for users of the Sun PCI High Speed Quad Port
Serial Interface Adapter from Oracle. Information provided includes adapter
installation, software installation and configuration, utilities, cable pin-outs and
signals, and null modem cable requirements. This document is intended for use by
either first-time or experienced users.
If you have just acquired this product, review the introductory sections and follow
the guidelines for installing and using the adapter.
Note – The Sun PCI High Speed Quad Port Serial Interface adapter is high-speed
serial-interface (HSI) adapter for PCI applications The adapter is referred to as
SunHSI/U in this manual.
How This Book Is Organized
This document is organized as follows:
Chapter 1 describes the products and lists system requirements.
Chapter 2 provides instructions for installing the adapter.
Chapter 3 contains the SunHSI software installation instructions.
Chapter 4 describes the utilities supplied with the SunHSI software.
Appendix A lists the cable pin assignments and signals.
Appendix B provides information on external clocking and the null modem cable.
Appendix C explains the inverted data and clock signals for T1.
xvii
Appendix D gives an overview of the SunVTS diagnostic software.
Appendix E provides instructions for viewing the man pages.
Typographic Conventions
Typeface
Meaning
Examples
AaBbCc123
The names of commands, files,
and directories; on-screen
computer output
Edit your.loginfile.
Use ls-ato list all files.
% You have mail.
What you type, when contrasted % su
with on-screen computer output
AaBbCc123
Password:
Book titles, new words or terms, Read Chapter 6 in the User’s Guide.
AaBbCc123
words to be emphasized.
Replace command-line variables
with real names or values.
These are called class options.
You must be superuser to do this.
To delete a file, type rmfilename.
Note – Characters display differently depending on browser settings. If characters
do not display correctly, change the character encoding in your browser to Unicode
UTF-8.
Related Documentation
The documents listed as online are available at:
Part
Application
Title
Number
Format
Location
Installation
Sun PCI High Speed Quad Port Serial Interface Adapter 819-1207
PDF,
Online
HTML
Issues & updates Sun PCI High Speed Quad Port Serial Interface Adapter 819-1208
PDF,
Online
Release Notes
HTML
xviii Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
Documentation, Support, and Training
These web sites provide additional resources:
Sun Function
Documentation
Support
URL
Training
Document Feedback
Submit comments about this document by clicking the Feedback [+] link at:
http://docs.sun.com/. Include the title and part number of your document with
your feedback:
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide, part number
819-1207-11
Preface
xix
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
CHAPTER
1
This chapter includes the following topics:
■
■
■
“Product Description” on page 1
“Features” on page 2
“Hardware and Software Requirements” on page 3
Product Description
The Sun PCI High Speed Quad Port Serial Interface adapter is high-speed serial
adapter in this manual. The adapter offers comprehensive hot-plug compatibility
with Solstice WAN software packages available through Sun. The SunHSI software
is a transparent interface on the SunHSI/U adapter, providing a compliant
environment for SunLink WAN packages operating on similar Sun communication
modules.
The SunHSI/U adapter (see FIGURE 1-1) is an intelligent, four-port communication
controller with onboard CPU and memory dedicated to WAN communication
functions. This architecture operates much more efficiently at high data rates than
unintelligent WAN modules. Onboard intelligence allows the workstation or server to
be off-loaded from many of the low-level communication tasks that it must perform
when there is no native intelligence on the controller.
1
FIGURE 1-1 SunHSI/U Adapter
The adapter comes with the RS-449 industry standard connectors (for example,
DB-37).
The protocols that operate with the SunHSI/U adapter include the Solstice X.25 and
Solstice Point-to-Point Protocol (PPP). The SunHSI/U adapter conforms to the Sun
Synchronous Serial Driver Interface Specification.
Features
■
■
■
■
■
■
■
■
Four synchronous RS-449 serial ports
Each port can be independently configured
T1/E1 transfer speed simultaneously on all four ports
Works in 3.3 Volt 66 MHz and 5 Volt 33 MHz PCI slots
Increased RS-232 support for data transmission range, up to 100 Kbps
Meets PCI local bus specification, rev. 2.2
Oracle Solaris 64-bit and 32-bit Operating System compatibility
Hot-plug capability
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
Hardware and Software Requirements
The hardware and software requirements for the SunHSI/U adapter are listed in
TABLE 1-1.
TABLE 1-1
Hardware and Software Requirements
Sun Blade 100, 150, 1500, 1000, 2000, 2500
Sun Systems
Workstations
Servers
Sun Fire V210, V240, 280R, V440, V480, V490, V880, V890, V1280, E2900,
E6900/E4900, 15K/12K, E25K/E20K
NEBS-certified Netra 240, 440, 1280
servers
Operating Systems
Solaris 10, Solaris 9, and Solaris 8
SunHSI Software (PCI device drivers, man pages, and utilities)
†
SunHSI/P 3.1 or newer
Diagnostics Version
Solaris 10 SunVTS 6.0 and subsequent compatible releases
Solaris 9 SunVTS 5.0 and subsequent compatible releases
Solaris 8 SunVTS 4.0 and subsequent compatible releases
†
The Sun HSI/P software is downloadable from the Sun Download Center at:
Chapter 1 Product Overview
3
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
CHAPTER
2
SunHSI/U Adapter Installation
This chapter describes how to install the adapter in your system and includes the
following topics:
■
■
■
“Installation Process” on page 5
“To Install the Adapter” on page 5
“External Cabling” on page 6
Installation Process
A simplified version of the installation process follows:
1. Install the adapter (see “To Install the Adapter” on page 5).
2. Install the SunHSI PCI software (see “SunHSI PCI Software Installation” on
page 9).
3. Test the installation (see “To Test the Installation” on page 3-14).
▼ To Install the Adapter
Caution – Electronic components on printed circuit boards are extremely sensitive
to static electricity. Ordinary amounts of static electricity generated by your clothing
or work environment can damage the electronic equipment. When installing the
SunHSI/U adapter in a system, use anti-static grounding straps and antistatic mats
to help prevent damage due to electrostatic discharge.
5
Note – Refer to your system installation guide or service manual for detailed
instructions for the following steps.
1. Power off your system, using the standard shutdown procedures described in
the Solaris Handbook for Sun Peripherals or your system service manual.
The Solaris Handbook for Sun Peripherals is shipped with the Solaris OS software
2. Remove the cover from the unit to access the card slots and connectors.
3. Select an available 3.3 Volt or 5 Volt PCI slot and remove the slot filler panel.
4. Insert the adapter into the PCI connector of the system unit.
Ensure that the front plate on the adapter mounts flush with the chassis panel
opening.
5. Install the front plate screw to secure the adapter into the chassis.
This also provides a chassis ground connection to the adapter.
6. Reinstall the cover on the unit.
8. Connect any cables from the peripheral devices to the RS-449 connectors on the
adapter’s cable.
9. Turn power back on and allow the system to reboot.
This completes the hardware installation. Proceed to “SunHSI PCI Software
Installation” on page 9.
External Cabling
The SunHSI/U adapter provides external connectivity through a passive cabling
system. A hydra-style connector provides connectivity to four RS-449 devices by
means of four DB-37 female connectors in a DTE configuration.
Note – Always use shielded twisted pair RS-449 cables with your SunHSI/U
adapter.
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
RS-232 to RS-449 Connections
In order to connect RS-232 devices to the adapter, you need to install an externally
powered RS-449 to RS-232 interface converter to each DB-37 connector on which you
intend to connect an RS-232 device. A converter is necessary because of
incompatibilities between RS-232 and RS-449 signal levels.
To obtain an externally powered RS-232 to RS-449 interface converter, contact:
Black Box Corporation at: http://www.blackbox.com
Note – Use only externally powered RS-449 devices with the SunHSI/U adapter.
Chapter 2 SunHSI/U Adapter Installation
7
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
CHAPTER
3
SunHSI PCI Software Installation
following sections:
■
■
■
■
“Installation Overview” on page 9
“Before Installing the Software” on page 11
“Installing the Software” on page 12
“Configuring the Software” on page 14
Installation Overview
Software for unbundled products is distributed in the form of software packages.
The SunHSI PCI software package can be downloaded from the Sun Download
Center at:
You can use the pkgadd command to install software packages, to spool software
packages for installation at a later date, or to remove software packages from your
system. For more information see the Solaris System Administration Guide. When
you have completed the software installation and run the postinstallation script, you
will have created the software directories and files illustrated in FIGURE 3-1 and
FIGURE 3-1.
Note – If you are upgrading to the SunHSI/U adapter from the SunHSI/P adapter
or if you are running a SunHSI/P adapter along with the SunHSI/U adapter,
youmust upgrade the SunHSI software to the latest version.
9
FIGURE 3-1 SunHSI Software Directories and Files
root
/kernel
/drv
/opt
/SUNWconn
/bin
/man
/HSIP
HSIP
/sparcv9
HSIP
/man1m
/man7d
hsip.7d*
hsip_init*
hsip_loop*
hsip_stat*
/bin
/man
hsip_init.1m*
hsip_loop.1m*
hspi_stat.1m*
/man1m
/man7d
hsip.7d
hsip_init
hsip_loop
hsip_stat
hsip_init.1m
hsip_loop.1m
hsip_stat.1m
* Signifies a symbolic link.
FIGURE 3-2 SunHSI Devices Created by the Postinstall Script
root
/dev
/hihp8
/hihp9
/hihp10
/hihp11
Board 3
/hihpn
/hihpn
/hihpn
/hihpn
Board N
/hihp0
/hihp1
/hihp2
/hihp3
Board 1
/hihp4
/hihp5
/hihp6
/hihp7
Board 2
/hihp
Clone device
(Control Port)
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
Before Installing the Software
Verifying the Software and Hardware
Requirements
Before installing the software, answer the following questions:
■
Does your system have any available 3.3V or 5V PCI slots?
■
Have you downloaded the SunHSI software from the Sun Download Center at:
■
■
What is the installation directory (default directory is /opt)?
Do you have the superuser password for both the system where the software is to
be installed and the system with download software, if different?
■
Does your system have enough disk space?
Use both the following commands to check for disk space:
# df -k /opt
# df -k /
TABLE 3-1
Required Disk Space
SunHSI Package Name
Default Installation Directory
Approximate Space Required
1 Mbyte
SUNWhsip
/
SUNWhsipm and SUNWhsipu /opt
1 Mbyte total
▼ To Remove Older Versions of the Software
Caution – Do not overwrite any existing SunHSI software packages. If you install
the SunHSI software packages over existing SunHSI software packages, you will
have two instances of the software packages. This might cause problems when
installing or backing out of software patches.
Chapter 3 SunHSI PCI Software Installation
11
Before installing the SunHSI PCI software on your system, check your system to see
if previous versions of the SunHSI software are installed. If older SunHSI software
exists, you must remove this software before installing the new SunHSI software.
●
Using the pkginfocommand, check the system for installed SunHSI software
packages:
system SUNWhsip SunHSI/P Driver for PCI
system SUNWhsipm SunHSI/P Man Pages for PC
system SUNWhsipu SunHSI/P Utilities for PCI
If no SunHSI packages are installed, skip to the next section,“Installing the
Software” on page 12, to continue with the software installation.
If there are SunHSI packages installed, remove them by logging on as superuser
(root) and typing the following command:
# /usr/sbin/pkgrm SUNWhsip SUNWhsipu SUNWhsipm
Installing the Software
The SunHSI PCI driver, utilities, and man pages are distributed in the standard
Solaris pkgadddistribution format. The pkgaddutility loads the SUNWhsip,
SUNWhsipm, and SUNWhsipupackages onto the system from the distribution media.
▼ To Install the SunHSI Software
1. Access the directory where the SunHSI software has been downloaded.
# cd download-directory
where download-directory is the name of the directory where the SunHSI software
was downloaded.
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
2. Log in as superuser or change to superuser.
You must possess superuser privileges to invoke the following commands. This
ensures that all preinstallation scripts in the software package will be executed
with superuser privileges.
# /usr/bin/su
Password: superuser-password
3. Using the pkgadd command, install the software packages as follows:
# pkgadd -d /download-directory/sunhsip_3_1/Product
The following packages are available:
SUNWhsip SunHSI/P Driver for PCI 3.1,REV=2005.xx.xx
SUNWhsipm SunHSI/P Man pages for PCI 3.1,REV=2005.xx.xx
SUNWhsipu SunHSI/P Utilities for PCI 3.1,REV=2005.xx.xx
Select package(s) you wish to process (or ‘all’ to process
all packages). (default: all) [?,??,q]: all
where download-directory is the name of the directory where the SunHSI software was
downloaded.
a. Type allor leave blank then press the Return key to continue the
installation of the driver software.
If the pkgaddutility warns you that some scripts must be executed with
superuser permissions, type y.
4. After successful completion of the package installation, reboot the system
using the reconfigure option.
a. Synchronize the hard disks and halt the system, using the following
commands.
# /usr/sbin/sync
# /usr/sbin/halt
b. At the okprompt, type the bootcommand with the -roption:
ok boot -r
Chapter 3 SunHSI PCI Software Installation
13
5. After the system reboots, verify the installation by typing the following
commands:
# /usr/bin/pkginfo | grep SUNWhsip
system SUNWhsip SunHSI/P Driver for PCI
system SUNWhsipm SunHSI/P Man Pages for PC
system SUNWhsipu SunHSI/P Utilities for PCI
# modinfo | grep HSIP
126 7bb24000 17708 150 1 HSIP (PT-PCI334 Driver)
# grep HSIP /etc/path_to_inst
"/ssm@0,0/pci@18,700000/pci1214,334a@2" 0 "HSIP"
The output shows that the packages are installed, the driver is loaded, and that
the software is mapped to the adapter.
▼ To Test the Installation
●
Type the following command (replace n with the adapter port you are testing):
# hsip_loop -c 100 -l 2048 -s 2048000 -t 1 hihpn
This command runs an internal loopback test. For more information, see the
hsip_loop(1M) man page.
Configuring the Software
To configure the adapter for the Point-to-Point Protocol (PPP), see “To Configure for
Point-to-Point Protocol” on page 3-15. Also refer to the Solaris System Administration
Guide: Network Services documentation for the version of Solaris that you are
running. These documents are available from the following web site:
To configure the adapter for the X.25 9.2 protocol, refer to the Solstice X.25 9.2
Administration Guide (806-1234). The X.25 9.2 documents are available from the
following web site:
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
▼ To Configure for Point-to-Point Protocol
1. Change to the /etc/pppdirectory and create an executable file called
conf_hsip, containing the following information:
#!/bin/ksh -x
DEVICE=‘echo $DEVICE | sed ‘s/?dev?//’’
/opt/SUNWconn/bin/hsip_init $DEVICE speed=2048000 mode=fdx loopback=no \
nrzi=no txc=baud rxc=rxc txd=txd rxd=rxd signal=no 2>&1 > /dev/null
2. Create another executable file called demand, containing the following
information:
if [ -f /var/run/ppp-demand.pid ] &&
/usr/bin/kill -s 0 ‘/bin/cat /var/run/ppp-demand.pid’
then
:
else
env DEVICE=hihp0 /usr/bin/pppd hihp0 :qa1b-hihp0 call far-hsip
env DEVICE=hihp1 /usr/bin/pppd hihp1 :qa1b-hihp1 call far-hsip
env DEVICE=hihp2 /usr/bin/pppd hihp2 :qa1b-hihp2 call far-hsip
env DEVICE=hihp3 /usr/bin/pppd hihp3 :qa1b-hihp3 call far-hsip
fi
3. Change to the /etc/ppp/peersdirectory and create an executable file called
far-hsip, containing the following information:
connect ‘/etc/ppp/conf-hsip’
local
sync
noauth
0:
ipcp-accept-local
nodefaultroute
passive
persist
noccp
nopcomp
novj
noaccomp
4. Add the client site hosts on the server machine and add the server site hosts on
the client machine.
a. Edit the server’s /etc/hostsfile and add the client site local hosts.
Chapter 3 SunHSI PCI Software Installation
15
b. Edit the client’s /etc/hostsfile and add the server site local hosts.
Note – Both IP addresses have to be on the same subnet.
Refer to the hosts(4) man page and the sample /etc/hostsfiles:
#Server site (/etc/hosts)
#=======================
#local
# Client site (/etc/hosts)
#=======================
#local
192.10.10.10 qa8a-hihp0
193.10.10.10 qa8a-hihp1
194.10.10.10 qa8a-hihp2
195.10.10.10 qa8a-hihp3
192.10.10.20 qa1b-hihp0
193.10.10.20 qa1b-hihp1
194.10.10.20 qa1b-hihp2
195.10.10.20 qa1b-hihp3
#remote
#remote
192.10.10.20 qa1b-hihp0
193.10.10.20 qa1b-hihp1
194.10.10.20 qa1b-hihp2
195.10.10.20 qa1b-hihp3
192.10.10.10 qa8a-hihp0
193.10.10.10 qa8a-hihp1
194.10.10.10 qa8a-hihp2
195.10.10.10 qa8a-hihp3
5. Edit the /etc/netmasksfile as follows:
192.10.10.0 255.255.255.0
193.10.10.0 255.255.255.0
194.10.10.0 255.255.255.0
195.10.10.0 255.255.255.0
6. Start the PPP connection by typing the following commands:
/etc/rc2.d/S47pppd stop
/etc/rc2.d/S47pppd start
16
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
CHAPTER
4
SunHSI Utilities
page to get more information on the commands. Also see “Viewing the Man Pages”
on page 41.
This chapter includes the following topics:
■
■
■
“hsip_initUtility” on page 17
“hsip_loopUtility” on page 20
“hsip_statUtility” on page 21
Note – You need to be superuser (root) in order to run the hsip_init,
hsip_loop, or hsip_statutilities.
hsip_initUtility
modes common to synchronous serial lines. This modification is needed for the
operation of some communications packages and is useful in troubleshooting a link.
See the hsip_init(1M) man page for details.
The hsip_init utility includes options for T1 compatibility and operating modes. See
“T1 Compatibility Options” on page 18 and “Operating Modes Options” on page 18
for information on these options.
17
T1 Compatibility Options
The version of the hsip_initutility shipped with the SunHSI software has options
that enable you to invert data and clock signals to accommodate the requirements of
T1 or CEPT transmission equipment. The hsip_initparameters that allow for
inversion are:
■ txd– transmit data signal
■ rxd– receive data signal
■ txc– transmit clock signal
■ rxc– receive clock signal
The effect of the default settings for all of these parameters is that SunHSI software
does not invert the data or clock signal controlled by the parameter. To invert a
signal, you specify a setting of the form param-name=-paramname, for example,
txc=-txc.
As an example, suppose you want to invert the transmit and receive data signals on
the first SunHSI/U port (port 0) on the second SunHSI/U adapter in your system. To
do so, enter the following command:
To invert both clock and data signals, enter:
# hsip_init hihp4 txd=-txd rxd=-rxd txc=-txc rxc=-rxc
Appendix C discusses the background and requirements for these inverted settings.
Operating Modes Options
This section describes the operating modes that you can set with the hsip_init
utility.
The SunHSI software operates in two main operating modes, the high-level data link
control (HDLC) mode and the IBM (SDLC) mode. The HDLC mode always operates
in a full-duplex, point-to-point fashion. While the IBM mode defaults to a
full-duplex, point-to-point, operation.
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
HDLC Mode
The default operating mode used by the SunHSI software is the HDLC full-duplex
protocol (mode=fdx). In this mode the transmitter is always enabled. The
transmitter sends flag bytes continuously when it is not sending a data frame.
If no message is currently being transmitted, the driver will attempt to start sending
its next message. At this point the driver indicates that it is busy transmitting, to
prevent the transmission of another message concurrently. The driver also activates
a mechanism that ensures that the transmit operation will not hang if the hardware
is not responding.
When the transmission is completed, the busy mechanism previously set is cleared
and the next message can be transmitted. If the transmission is hung an abort
sequence is sent instead of the cyclic redundancy check (CRC), so that the receiver
will not interpret the frame as valid data. The message is discarded, and the output
error statistic is incremented, which allows for a proper recovery by higher level
protocols.
The received data is buffered until a complete frame has been received. If any error
occurs during the reception of a frame, the appropriate statistic is incremented and
the frame is discarded.
IBM (SDLC) Mode
SDLC mode is designed to support IBM system network architecture (SNA)
communications. It uses most of the same protocols used in HDLC mode, with two
major exceptions:
■
When the line is idle, instead of sending flag bytes the transmitter is disabled.
■
The request-to-send (RTS) and clear-to-send (CTS) signals are used to gate
transmission.
IBM Full-Duplex Mode
When the SunHSI software is set to this mode (mode=ibm-fdx), the software uses a
full-duplex point-to-point communication protocol. Both ends of the link are
expected to have RTS and CTS signals asserted at all times when data is being
exchanged. When starting a message transmission, the interface raises the RTS signal
and expects the CTS signal to be asserted immediately. If this is not done, all
messages currently queued for transmission are discarded, and the write operation
returns an error.
Chapter 4 SunHSI Utilities
19
If the CTS signal drops before the frame transmission is complete, the frame is
discarded and the abort error statistic is incremented. If the transmission underruns,
an abort sequence is not sent and the frame is silently discarded. The RTS signal
remains asserted until the data transmission is complete.
IBM Half-Duplex Mode
Half-duplex is a submode of the IBM mode (mode=ibm-hdx). Half-duplex mode
operates in the same manner as full-duplex mode except that transmission cannot
occur while receiving, and vice-versa. When a transmission is completed, the RTS
signal is dropped. Dropping the RTS signal tells the remote station to begin
transmitting if it is ready to.
IBM MultiPoint Mode
In a multipoint configuration (mode=ibm-mpt), more than two stations share a link.
This configuration is accomplished by designating one station as a primary station
and the rest as secondary stations. In this mode, the port acts as a secondary station.
The primary station arbitrates traffic on the link by polling the secondary stations, to
see if they are ready to transmit.
If a secondary station has data to transmit, it will raise its RTS signal and check for
CTS signals. When a CTS signal comes up the station may begin transmitting,
following the same rules for RTS and CTS signals used in half-duplex mode. When
the transmission is complete the secondary drops the RTS signal, which enables
another station to respond to a poll and begin transmitting. The RTS signal cannot be
dropped until the transmission is complete.
hsip_loopUtility
The hsip_looputility is high-speed, synchronous, serial loopback test program for
high-speed serial interface. The utility performs several loopback tests that exercise
the components of a serial communications link. See the hsip_loop(1M) man page
for more information.
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
hsip_statUtility
The hsip_statutility reports the event statistics maintained by the SunHSI device
driver. The report might be a single snapshot of the accumulated totals, or a series of
samples showing incremental changes. At the beginning of the report, the device
name being used to query a particular device appears. See the hsip_stat(1M) man
page for more information.
Chapter 4 SunHSI Utilities
21
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
APPENDIX
A
Cable Pin Assignments & Signals
This appendix includes the following information:
■
“Pin Assignments” on page 23
“Interface Signals” on page 27
■
Pin Assignments
A shielded, hydra-style breakout cable providing four 37-pin, D-shell (DB-37) DTE
connectors is available for the SunHSI/U adapter. Since there are not enough wires to
create the signal ground (pin 19) connections, use the shield ground (pin 1) of the
DB-37 connector for this signal. The pin assignments for the cabling and connectors
are shown in TABLE A-1.
TABLE A-1 RS-449 Connector Pin Assignments
80-Pin Amp.
Pin No.
RS-449
Signal Name
RS-449 DB-37
Pin No.
Description
1
2
3
4
5
6
7
8
9
RxD1(A)
RxD1(B)
DTR1(A)
DTR1(B)
TxD1(A)
TxD1(B)
RTS1(A)
RTS1(B)
TxC1(A)
6
Port 1 Receive Data
Port 1 Receive Data
Port 1 Data Terminal Ready
Port 1 Data Terminal Ready
Port 1 Transmit Data
Port 1 Transmit Data
Port 1 Request To Send
Port 1 Request To Send
Port 1 Transmit Clock
24
12
30
4
22
7
25
17
23
TABLE A-1 RS-449 Connector Pin Assignments (Continued)
80-Pin Amp.
Pin No.
RS-449
Signal Name
RS-449 DB-37
Pin No.
Description
10
11
12
13
14
15
16
17
18
19
20
TxC1(B)
TxCI1(A)
TxCI1(B)
DCD1(A)
DCD1(B)
DSR1(A)
DSR1(B)
CTS1(A)
CTS1(B)
RxC1(A)
RxC1(B)
35
5
Port 1 Transmit Clock
Port 1 Transmit Clock In
Port 1 Transmit Clock In
Port 1 Data Carrier Detect
Port 1 Data Carrier Detect
Port 1 Data Set Ready
Port 1 Data Set Ready
Port 1 Clear To Send
23
13
31
11
29
9
27
8
Port 1 Clear To Send
Port 1 Receive Clock
26
1
Port 1 Receive Clock
Shield Ground SG
RxD2(A)
Port 1 Shield Ground and Signal Ground
Port 2 Receive Data
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
6
RxD2(B)
DTR2(A)
DTR2(B)
TxD2(A)
TxD2(B)
RTS2(A)
RTS2(B)
TxC2(A)
TxC2(B)
TxCI2(A)
TxCI2(B)
DCD2(A)
DCD2(B)
DSR2(A)
DSR2(B)
CTS2(A)
CTS2(B)
24
12
30
4
Port 2 Receive Data
Port 2 Data Terminal Ready
Port 2 Data Terminal Ready
Port 2 Transmit Data
22
7
Port 2 Transmit Data
Port 2 Request To Send
Port 2 Request To Send
Port 2 Transmit Clock
Port 2 Transmit Clock
Port 2 Transmit Clock In
Port 2 Transmit Clock In
Port 2 Data Carrier Detect
Port 2 Data Carrier Detect
Port 2 Data Set Ready
Port 2 Data Set Ready
Port 2 Clear To Send
25
17
35
5
23
13
31
11
29
9
27
Port 2 Clear To Send
24
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
TABLE A-1 RS-449 Connector Pin Assignments (Continued)
80-Pin Amp.
Pin No.
RS-449
Signal Name
RS-449 DB-37
Pin No.
Description
39
40
RxC2(A)
RxC2(B)
8
Port 2 Receive Clock
26
1
Port 2 Receive Clock
Shield Ground SG
RxD3(A)
Port 2 Shield Ground and Signal Ground
Port 3 Receive Data
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
6
RxD3(B)
DTR3(A)
DTR3(B)
TxD3(A)
TxD3(B)
RTS3(A)
RTS3(B)
TxC3(A)
TxC3(B)
TxCI3(A)
TxCI3(B)
DCD3(A)
DCD3(B)
DSR3(A)
DSR3(B)
CTS3(A)
CTS3(B)
RxC3(A)
RxC3(B)
24
12
30
4
Port 3 Receive Data
Port 3 Data Terminal Ready
Port 3 Data Terminal Ready
Port 3 Transmit Data
22
7
Port 3 Transmit Data
Port 3 Request To Send
Port 3 Request To Send
Port 3 Transmit Clock
Port 3 Transmit Clock
Port 3 Transmit Clock In
Port 3 Transmit Clock In
Port 3 Data Carrier Detect
Port 3 Data Carrier Detect
Port 3 Data Set Ready
Port 3 Data Set Ready
Port 3 Clear To Send
25
17
35
5
23
13
31
11
29
9
27
8
Port 3 Clear To Send
Port 3 Receive Clock
26
1
Port 3 Receive Clock
Shield Ground SG
Port 3 Shield Ground and Signal Ground
Port 4 Receive Data
61
62
63
64
65
66
RxD4(A)
6
RxD4(B)
DTR4(A)
DTR4(B)
TxD4(A)
TxD4(B)
24
12
30
4
Port 4 Receive Data
Port 4 Data Terminal Ready
Port 4 Data Terminal Ready
Port 4 Transmit Data
22
Port 4 Transmit Data
Appendix A Cable Pin Assignments & Signals
25
TABLE A-1 RS-449 Connector Pin Assignments (Continued)
80-Pin Amp.
Pin No.
RS-449
Signal Name
RS-449 DB-37
Pin No.
Description
67
68
69
70
71
72
73
74
75
76
77
78
79
80
RTS4(A)
RTS4(B)
TxC4(A)
TxC4(B)
TxCI4(A)
TxCI4(B)
DCD4(A)
DCD4(B)
DSR4(A)
DSR4(B)
CTS4(A)
CTS4(B)
RxC4(A)
RxC4(B)
7
Port 4 Request To Send
Port 4 Request To Send
Port 4 Transmit Clock
Port 4 Transmit Clock
Port 4 Transmit Clock In
Port 4 Transmit Clock In
Port 4 Data Carrier Detect
Port 4 Data Carrier Detect
Port 4 Data Set Ready
Port 4 Data Set Ready
Port 4 Clear To Send
25
17
35
5
23
13
31
11
29
9
27
8
Port 4 Clear To Send
Port 4 Receive Clock
26
1
Port 4 Receive Clock
Shield Ground SG
Port 4 Shield Ground and Signal Ground
26
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
Interface Signals
Functional descriptions of the RS-449 interface signals are provided in TABLE A-2.
TABLE A-2 RS-449 Interface Signals
RS-449 Pin
No.
Signal Name
Function
1
Shield Ground
Enables tandem sections of shielded cable to retain continuity
through the connector.
19
Signal Ground (SG)
Transmit Data (TxD)
Receive Data (RxD)
Transmit Clock in (TxCI)
Directly connects the DTE circuit ground to the DCE circuit
ground, providing a path for DTE and DCE signal commons.
4/22
6/24
5/23
Used by the DTE to pass binary data to the DCE for
transmission over the communications channel.
Used by the DCE to pass binary data received from the
communications channel to the DTE.
Enables the DCE to transmit signal element timing to the DTE.
This enables the DTE Transmit Data signal on circuit TxD to be
in synchronization with On/Off transitions on this lead.
8/26
Receive Clock (RxC)
Transmit Clock (TxC)
Transitions on this lead enables the DTE to time data received
over circuit RxD.
17/35
Enables the DTE to provide transmit timing information to the
DCE so that the DTE can synchronize with data arriving over
the TxD lead.
7/25
9/27
Request to Send (RTS)
Clear to Send (CTS)
Used by the DTE to advise the DCE it is ready to transmit data.
Used by the DCE to advise the DTE that the DCE is ready to
send data over the communications channel.
11/29
12/30
13/31
Data Set Ready (DSR)
Used to advise the DTE of the Ready status on the DCE. In
most cases, this signal simply implies the unit is powered on.
Data Terminal Ready (DTR)
Data Carrier Detect (DCD)
Used by the DTE to advise the DCE it is ready to transmit or
receive.
The DCE uses this lead to advise the DTE that an incoming
signal on the communications channel is present. When first
initialized this signal is an indication to the DTE to expect data
momentarily.
Appendix A Cable Pin Assignments & Signals
27
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
APPENDIX
B
Null Modem Cable Requirements
A synchronous null modem cable is a specially-configured cable that simulates
modems that are connected back-to-back. When the distance between the two host
systems is not great, you may be able to use a null modem cable instead of a
synchronous modem or a synchronous modem eliminator.
The maximum distance a null modem cable can work is determined by the
specification for your serial port interface.
There are two steps you must perform to use a null modem cable for machine
supplied clocking:
Run hsip_init(see “Configuring Internal or External Clocking” on page 30) so that
the Sun system, in the absence of a synchronous modem, supplies clocking on the
serial line.
Note – You must run hsip_initeach time you reboot your system.
The following topics are included in this appendix:
■
“Configuring Internal or External Clocking” on page 30
“Building the Null Modem Cable” on page 30
■
29
Configuring Internal or External
Clocking
To configure an RS-449 port to provide transmit clocking for itself as well as receive
clocking for the other end of the link, set the txc(transmit clock) and rxc(receive
clock) parameters in hsip_initto baudand rxc, respectively. For example, the
following hsip_initcommand sets the data rate of the first Sun HSI serial port to
9600 bps and sets the clocking as just described:
# hsip_init hihp0 9600 txc=baud rxc=rxc
You enter such a command at both ends of a link if both sides are supplying clocking.
In the situation in which you have Sun systems at both ends of a link and have one
system supplying clocking for both sides, on the system that is not supplying the
clocking, you enter:
# hsip_init hihp0 9600 txc=txc rxc=rxc
Building the Null Modem Cable
To build a null modem cable, you can configure your own cable or use a standard
cable with an adapter box.
Note – Be sure to use shielded, twisted pair wire when building a null modem cable.
If you decide to use an adapter box, be sure to obtain an adapter that allows you to
change the pin configurations. Pre-configured adapters generally do not work with
synchronous protocols because they do not handle clock signals correctly.
30
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
RS-449 Null Modem Cable
TABLE B-1 and TABLE B-2 list the signals and names for RS-499 and X.21 circuits
TABLE B-1 RS-449 Signals
Circuit
TxD
RxD
TxC
TxCI
RxC
RTS
Name
Direction
Transmit Data
Receive Data
To DCE
From DCE
To DCE
Transmit Clock
Transmit Clock In
Receive Clock
Request to Send
Clear to Send
From DCE
From DCE
To DCE
CTS
DCD
DTR
DSR
SG
From DCE
From DCE
To DCE
Data Carrier Detect
Data Terminal Ready
Data Set Ready
Signal Ground
From DCE
TABLE B-2 X.21 Signals
Circuit
Name
Direction
G
T
R
C
I
Signal Ground
Transmit
To DCE
Receive
From DCE
To DCE
Control
Indication
Signal Element Timing
Byte Timing
From DCE
From DCE
From DCE
S
B
Appendix B Null Modem Cable Requirements
31
FIGURE B-1 illustrates a synchronous null modem cable that allows you to connect
two Sun systems that each supply clocking, using the RS-449 interface. Each Sun
supplies clocking on pins 17 and 35. The null modem cable routes this clocking to
pins 8 and 26 on the opposite side to provide receive clocking.
Because the RS-449 interface is balanced, there are two pins for each signal. For
example, Transmit Data (TxD), pins 4 and 22, is connected to Received Data (RxD),
pins 6 and 24. This means that pin 4 is connected to pin 6 and pin 22 is connected to
pin 24.
FIGURE B-1 Null modem Cable (Both Suns Supply Clocking)
TxD (4,22)
RxD (6,24)
RTS (7,25)
CTS (9,27)
DSR (11,29)
SG (19)
TxD (4,22)
RxD (6,24)
RTS (7,25)
CTS (9,27)
DSR (11,29)
SG (19)
DCD (13,31)
DCD (13,31)
RxC (8,26)
RxC (8,26)
DTR (12,30)
TxC (17,35)
Sun workstation
DTR (12,30)
TxC (17,35)
Sun workstation
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
FIGURE B-2 illustrates a synchronous null modem cable that allows you to another
system, Sun or non-Sun, using the RS-449 interface. The Sun supplies both the
transmit and receive clocks for the other system. Note that this null modem cable is
not symmetrical.
FIGURE B-2 Null modem Cable (Sun System Supplies Clocking for Both Sides)
TxD (4,22)
RxD (6,24)
RTS (7,25)
CTS (9,27)
DSR (11,29)
SG (19)
TxD (4,22)
RxD (6,24)
RTS (7,25)
CTS (9,27)
DSR (11,29)
SG (19)
DCD (13,31)
DCD (13,31)
RxC (8,26)
DTR (12,30)
TxC (17,35)
TxCI (5,23)
RxC (8,26)
DTR (12,30)
Sun workstation
that supplies clocking
Sun or foreign
device
Appendix B Null Modem Cable Requirements
33
X.21 to RS-449 Converter
FIGURE B-3 illustrates the pin connections required for an X.21 to RS-449 converter.
FIGURE B-3 X.21 to RS-449 Converter
T(2,9)
TxD (4,22)
RxC (8,26)
S (6,13)
TxCI (5,23)
RTS (7,25)
C (3,10)
CTS (9,27)
RxD (6,24)
DCD (13,31)
SG (19)
R (4,11)
I (5,12)
G (8)
X.21 interface
(15 pin connector)
RS-449 Interface
Workstation
(37 Pin Connector)
When using an X.21 conversion you must perform the following hsip_init
operation:
#hsip_init hihp0 9600 txc=txc rxc=rxc
Note – Both receive and transmit clock inputs (RxC and TxCI) need a clock signal if
txcis set to txcand rxcis set to rxc.
34
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
APPENDIX
C
This appendix includes the following topics:
■
“Data Signal Inversion” on page 35
“Clock Signal Inversion” on page 37
■
Data Signal Inversion
The requirement for inverting data signals arises from the “ones density” problem
you encounter with most T1 transmission lines in North America. The T1
transmission scheme uses a signaling mechanism known as Alternate Mark Inversion
(AMI), in which one bits are represented by a positive or negative pulse, while zero
bits are represented by the absence of a pulse. In this scheme, the polarity of each
pulse must be the opposite of the polarity of the pulse which immediately preceded
it. This signaling scheme makes it possible to embed a reference clock for the data
into the data stream itself.
Various types of T1 transmission equipment, such as Data Service Units (DSU),
Channel Service Units (CSU), repeaters, and various telephone central office
equipment, must be able to keep a phase locked loop (PLL) circuit locked on to this
reference clock. This PLL circuit uses the pulses generated when one bits are
transmitted to lock the embedded clock to a local reference oscillator. To keep the
PLL circuit locked on the extracted clock, a certain density of pulses (one bits) must
be guaranteed. For North American T1 lines, the density requirement dictates that at
least one out of every 16 bits must be a one (see AT&T Technical Publication 62411).
Another way of stating this is that no more than 15 consecutive zero bits can occur
anywhere in the data stream.
T1 lines were originally intended to carry voice traffic, wherein the digitized voice
signals could be altered to meet the ones-density requirement by forcing every eighth
bit of a voice channel to be a one. This practice introduces a small—but virtually
35
inaudible—amount of distortion in the voice signal. Digital data streams between
two computers are another matter, since the corruption of even one data bit causes a
packet to be rejected. Note that in a typical data packet it is quite easy to produce bit
patterns that violate the ones-density requirement. A random file could easily
contain a sequence of bytes that would produce 16 or more consecutive zero bits if
transmitted serially.
There are many different schemes for circumventing the ones-density requirement.
The most common technique simply reserves every eighth bit of the signal for a
“density bit” and forces this bit to be a one. Obviously, these bits are not available for
data transmission, which means that 12.5 percent of the bandwidth of the T1 line is
wasted. When you consider that the lease cost for a coast-to-coast T1 line can be
exceedingly expensive, this waste of bandwidth can be unacceptable. There are
alternatives.
Bipolar with 8-Zero Substitution
One of them uses a special code that transmission equipment can generate when
using the AMI signalling scheme. This special code depends on the fact that two
successive one bits that are represented by pulses of the same polarity result in a
signal known as a “Bipolar Violation.” A CSU can be designed so that it will
automatically replace any string of eight consecutive zeros with a special code
pattern that contains two of Bipolar Violations. A compatible, receiving CSU
recognizes this special code and converts it back to a pattern of eight zeros. This
technique is known by the acronym B8ZS, which stands for Bipolar with 8-Zero
Substitution.
All CEPT lines (the European equivalent of T1) mandate the use of a variant of B8ZS
that holds the density requirement down to no more than three consecutive zeros.
However, telephone companies in North America have been slow to adopt B8ZS,
because it would entail a significant capital investment. Therefore, the B8ZS solution
will not solve the ones-density problem in the short term.
HDLC Zero Insertion Algorithm
An alternative to B8ZS—an alternative used by the SunHSI/P product—makes use of
the fact that the HDLC framing rules specify that any data stream that contains five
or more consecutive one bits requires that the transmitting end insert a zero bit after
the fifth one bit. This guarantees that the HDLC flag pattern 01111110(hex 7E) does
not occur randomly inside a frame. The receiving end must automatically discard the
zero bit that follows a pattern of five consecutive ones. So, HDLC framing, which is
used by SunHSI/P, guarantees that, except for the flag pattern, in any set of six bits,
at least one bit will be a zero. If you include the flag pattern, you can say that in any
set of seven bits, at least one bit will be a zero.
36
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
By inverting the data signal with HDLC framing on both ends of a link, the HDLC
zero insertion algorithm becomes a ones insertion algorithm. This guarantees that in
any set of seven bits, at least one bit will be a one. Thus, the HDLC data stream meets
the density requirements of North American T1 lines without sacrificing any
bandwidth.
Clock Signal Inversion
The need to invert clock lines is separate from the need to invert data lines. Most
computer, modem, and terminal vendors adhere to an industry standard
specification known as RS-334. This specification defines the relationship between a
data bit and a reference clock on a synchronous serial link. The specification also says
that a device should transmit data with reference to the rising edge of the clock
signal and that data should be received with reference to the falling edge of the clock
signal.
When using long cables or cables not carrying a clock signal, a phase shift may occur
causing a high number of errors. In such cases, inverting the clock signal may correct
the phase shift. You may also need to invert the clock signal when connecting a
SunHSI/P port to equipment not adhering to the RS-334 standard.
Appendix C T1 Inverted Data and Clock Signals
37
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
APPENDIX
D
SunVTS Diagnostic Testing
interface, and is used to verify the configuration and functionality of most hardware
controllers and devices. The SunVTS software operates primarily from a graphical
user interface, enabling test parameters to be set quickly and easily while a
diagnostic test operation is being performed.
Refer to the SunVTS documents (see TABLE D-1) for instructions on how to run and
monitor the sunlink diagnostic. These SunVTS documents are available online at the
following URL:
Select the document for the Solaris release on your system.
TABLE D-1 Sun VTS Documentation
Title
Description
SunVTS User’s Guide
Describes the SunVTS diagnostic environment.
SunVTS Test Reference Manual Describes each SunVTS test (including sunlink) and
describesthe various test options and command-line
arguments.
SunVTS Quick Reference Card Provides an overview of the user interface.
Using the SunVTS sunlinkTest
The sunlink diagnostic test, which is shipped with the SunVTS software, verifies the
functionality of SunHSI adapters. This test can be run from the SunVTS user
interface, or it can be run from the command line. Refer to the SunVTS Test Reference
Manual for more information about the sunlinktest.
39
Note – Some of the sunlinktests require a RS-449 loopback plug, which can be
ordered through Sun (part number 540-1430).
40
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
APPENDIX
E
Viewing the Man Pages
The following man pages are included with the SunHSI software:
■ hsip(7d)
■ hsip_init(1m)
■ hsip_loop(1m)
■ hsip_stat(1m)
If you cannot view these man pages, you need to add the /opt/SUNWconn/man/
directory to your MANPATHenvironment variable. Depending on the UNIX shell you
are using, this variable might be defined in one of a number of startup files.
Man Pages
▼ To View Man Pages in the C Shell Environment
1. Examine your $HOME/.loginand $HOME/.cshrcfiles to locate the MANPATH
variable.
2. Using a text editor, add the following line to the end of the file containing the
MANPATHvariable.
setenv MANPATH “/opt/SUNWconn/man/:$MANPATH”
41
If neither of the files in Step 1 contains the MANPATHvariable, add the following
line to the end of one of the files, or contact your system administrator for
assistance.
setenv MANPATH “/opt/SUNWconn/man/”
3. Use the source command on the file you edited to make the changes effective in
your current window.
For example, if you added the MANPATHline to the .loginfile, you would type:
hostname% source $HOME/.login
Note – If you log out and then back into your system, you update the MANPATH
variable in all command windows and shells.
▼ To View Man Pages in Bourne or Korn Shell
Environments
1. Using a text editor, add these two lines to the end of the $HOME/.profilefile.
MANPATH=/opt/SUNWconn/man:$MANPATH
export MANPATH
If this file did not already contain this variable, add the following two lines to the
end of the file, or contact your system administrator for assistance.
MANPATH=/opt/SUNWconn/man
export MANPATH
2. Make the changes effective in your current window.
$ . $HOME/.profile
Note – If you log out and then back into to your system, you update the MANPATH
variable in all command windows and shells.
42
Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
Glossary
AMI
bps
Alternate Mark Inversion
Bits per second
CEPT
CSU
CPU
DSU
E1
European Conference of Postal and Telecommunications Administrations
Channel Service Unit
tCentral Processing Unit
Data Service Unitr.
European equivalent of T1
High-Level Data Link Control
MegaHertz
HDLC
MHz
PLL
Phase-locked loo
PPP
Point-to-Point Protocol
SDLC
SNA
T1
Synchronous Data Link Control
System Network Architecture
A communications service providing leased-line support for 1,554,000 bps
on twisted copper wire.
WAN
Wide Area Network
43
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Sun PCI High Speed Quad Port Serial Interface Adapter User’s Guide • May 2010
|